Linux内核网络栈实现分析（九）传输层之UDP协议（下）

本文分析基于Linux Kernel 1.2.13

原创作品，转载请标明http://blog.csdn.net/yming0221/article/details/7549340

更多请查看专栏，地址http://blog.csdn.net/column/details/linux-kernel-net.html

作者：闫明

注：标题中的”（上）“，”（下）“表示分析过程基于数据包的传递方向：”（上）“表示分析是从底层向上分析、”（下）“表示分析是从上向下分析。

上篇分析了应用层经过BSD socket层到INET socket层的函数调用关系和数据的处理流程，INET层会调用具体的传输层协议，还是以UDP协议为例

udp_write()函数

static int udp_write(struct sock *sk, unsigned char *buff, int len, int noblock,

      unsigned flags)

{

    return(udp_sendto(sk, buff, len, noblock, flags, NULL, 0));

}

在分析udp_sendto()函数之前，先了解一下sockaddr_in结构，这是标准的网络接口地址结构的定义

struct sockaddr_in {

  short int     sin_family; /* Address family   地址族 */

  unsigned short int    sin_port;   /* Port number  端口号     */

  struct in_addr    sin_addr;   /* Internet address 网络地址    */


  /* Pad to size of `struct sockaddr'. */

  unsigned char     __pad[__SOCK_SIZE__ - sizeof(short int) -

            sizeof(unsigned short int) - sizeof(struct in_addr)];

};

#define sin_zero    __pad       /* for BSD UNIX comp. -FvK  */

udp_sentdto()函数

static int udp_sendto(struct sock *sk, unsigned char *from, int len, int noblock,

       unsigned flags, struct sockaddr_in *usin, int addr_len)

{

    struct sockaddr_in sin;

    int tmp;


    /*

     *  Check the flags. We support no flags for UDP sending

     */

    if (flags&~MSG_DONTROUTE)

        return(-EINVAL);

    /*

     *  Get and verify the address.

     */


    if (usin) //如果usin不是空

    {

        if (addr_len < sizeof(sin))

            return(-EINVAL);

        memcpy(&sin,usin,sizeof(sin));

        if (sin.sin_family && sin.sin_family != AF_INET)

            return(-EINVAL);

        if (sin.sin_port == 0)

            return(-EINVAL);

    }

    else //usin为空

    {

        if (sk->state != TCP_ESTABLISHED)

            return(-EINVAL);

        sin.sin_family = AF_INET;//协议族

        sin.sin_port = sk->dummy_th.dest;//目的端口

        sin.sin_addr.s_addr = sk->daddr;//目的地址

    }


    /*

     *  BSD socket semantics. You must set SO_BROADCAST to permit

     *  broadcasting of data.

     */


    if(sin.sin_addr.s_addr==INADDR_ANY)//目的地址是全0地址，对应当前主机

        sin.sin_addr.s_addr=ip_my_addr();//将目的地址设为当前主机的网络地址


    if(!sk->broadcast && ip_chk_addr(sin.sin_addr.s_addr)==IS_BROADCAST)

            return -EACCES;         /* Must turn broadcast on first */


    sk->inuse = 1;


    /* Send the packet. */

    tmp = udp_send(sk, &sin, from, len, flags);//调用udp_send()真正的发送数据


    /* The datagram has been sent off.  Release the socket. */

    release_sock(sk);

    return(tmp);

}

udp_send()函数

static int udp_send(struct sock *sk, //要发送的数据包使用的协议对用的sock结构

                       struct sockaddr_in *sin,//目的端的标准的网络接口地址

                       unsigned char *from,//要发送的数据所在地址

                       int len,//发送数据的长度

                       int rt)

{

    struct sk_buff *skb;

    struct device *dev;

    struct udphdr *uh;

    unsigned char *buff;

    unsigned long saddr;

    int size, tmp;

    int ttl;


    /*

     *  Allocate an sk_buff copy of the packet.

     */


    size = sk->prot->max_header + len;//计算大小为UDP最长表头+ 数据长度

    skb = sock_alloc_send_skb(sk, size, 0, &tmp);//根据要发送的数据分配sk_buff结构空间并对当前套接字状态检查



    if (skb == NULL)

        return tmp;


    skb->sk       = NULL;    /* to avoid changing sk->saddr */

    skb->free     = 1;

    skb->localroute = sk->localroute|(rt&MSG_DONTROUTE);


    /*

     *  Now build the IP and MAC header.

     */


    buff = skb->data;//将skb中的数据指针赋值给buff指针

    saddr = sk->saddr;//本地地址

    dev = NULL;

    ttl = sk->ip_ttl;//生存时间

#ifdef CONFIG_IP_MULTICAST

    if (MULTICAST(sin->sin_addr.s_addr))

        ttl = sk->ip_mc_ttl;

#endif

    tmp = sk->prot->build_header(skb, saddr, sin->sin_addr.s_addr,

            &dev, IPPROTO_UDP, sk->opt, skb->mem_len,sk->ip_tos,ttl);//调用ip_build_header()创建IP报头和调用ip_send()创建MAC首部


    skb->sk=sk;  /* So memory is freed correctly */


    /*

     *  Unable to put a header on the packet.

     */


    if (tmp < 0 )

    {

        sk->prot->wfree(sk, skb->mem_addr, skb->mem_len);

        return(tmp);

    }


    buff += tmp;

    saddr = skb->saddr; /*dev->pa_addr;*/

    skb->len = tmp + sizeof(struct udphdr) + len;    /* len + UDP + IP + MAC */

    skb->dev = dev;


    /*

     *  Fill in the UDP header. 填写UDP的报头

     */


    uh = (struct udphdr *) buff;

    uh->len = htons(len + sizeof(struct udphdr));//数据包长度

    uh->source = sk->dummy_th.source;//本地端口

    uh->dest = sin->sin_port;//远端端口

    buff = (unsigned char *) (uh + 1);


    /*

     *  Copy the user data.

     */


    memcpy_fromfs(buff, from, len);//复制用户数据


    /*

     *  Set up the UDP checksum.

     */


    udp_send_check(uh, saddr, sin->sin_addr.s_addr, skb->len - tmp, sk);//计算UDP报头的校验和


    /*

     *  Send the datagram to the interface.

     */


    udp_statistics.UdpOutDatagrams++;


    sk->prot->queue_xmit(sk, dev, skb, 1);//调用IP层函数发送数据

    return(len);

}

这样要发送的数据填充的sk_buff结构中之后再对UDP数据包添加IP数据报头和MAC帧的首部。最后调用IP层的发送函数发送数据包。